BS EN ISO 22007-6:2015
Plastics. Determination of thermal conductivity and thermal diffusivity Comparative method for low thermal conductivities using a temperature-modulation technique
Označení normy: | BS EN ISO 22007-6:2015 |
Počet stran: | 22 |
Vydáno: | 2015-04-30 |
ISBN: | 978 0 580 87283 9 |
Status: | Standard |
BS EN ISO 22007-6:2015
This standard BS EN ISO 22007-6:2015 Plastics. Determination of thermal conductivity and thermal diffusivity is classified in these ICS categories:
- 83.080.01 Plastics in general
This part of ISO 22007 specifies a modulated temperature method realizing the measurement of thermal conductivity. An input of temperature deviation is less than 1 K, and a double lock-in method is applied to amplify the small temperature modulation.
ISO 22007-3 specifies one of the modulated temperature methods where the phase shift is measured in the thermally thick condition, kd >> 1 [k = (ω/2α)1/2, ω: angular frequency of temperature wave, α: thermal diffusivity, and d: thickness of the specimen]. In this condition, the backing material does not affect on the phase shift results on the sensor, on which temperature wave decays exponentially.
On the other hand, if kd << 1, the decay of temperature modulation is influenced by the backing materials. Based on this principle, this part of ISO 22007 specifies the method to determine the thermal conductivity of the sample (as a backing material), comparing the decay of temperature wave detected on both surfaces of the probe material.
Thermal conductivity is determined from the correlation between the thermal impedance and the decay ratio of amplitude using two reference materials measured at the same frequency and temperature.
The covering thermal conductivity range is adjusted with the reference materials and the probe materials. Basically, thermal conductivity is determined in the range from 0,026 W/mK to 0,6 W/mK.
In the case applying the method to inhomogeneous materials, cares must be taken to choose the appropriate measurement conditions in accordance with the thermal penetration depth.